Dynamics of Toxoplasma gondii differentiation

Parasite differentiation is commonly associated with transitions between complex life cycle stages and with long-term persistence in the host, and it is therefore critical for pathogenesis. In the protozoan parasite Toxoplasma gondii, interconversion between rapidly growing tachyzoites and latent encysted bradyzoites is accompanied by numerous morphological and metabolic adaptations. In order to explore early cell biological events associated with this differentiation process, we have exploited fluorescent reporter proteins targeted to various subcellular locations. Combining these markers with efficient in vitro differentiation and time-lapse video microscopy provides a dynamic view of bradyzoite development in living cultures, demonstrating subcellular reorganization, maintenance of the mitochondrion, and missegregation of the apicoplast. Bradyzoites divide asynchronously, using both endodyogeny and endopolygeny, and are highly motile both within and between host cells. Cysts are able to proliferate without passing through an intermediate tachyzoite stage, via both the migration of free bradyzoites and the fission of bradyzoite cysts, suggesting a mechanism for dissemination during chronic infection.     

Developmental differentiation between tachyzoites and bradyzoites of Toxoplasma gondii

An important event in the pathogenesis of toxoplasmosis is the interconversion between the bradyzoite and the tachyzoite stage of Toxoplasma gondii within the intermediate host. The factors that influence either cyst formation (bradyzoites) or reactivation (tachyzoites) are unknown. Uwe Gross, Wolfgang Bohne, Martine Soête and Jean Fran?ois Dubremetz here describe current knowledge about the mechanisms that might lead to the induction of stage differentiation of this protozoan parasite.     

Strain and stage specific variation in Toxoplasma gondii antigens

The antigenic profile of virulent (RH, ENT, Martin) and avirulent (RRA, DEG, ME49) Toxoplasma strains was compared directly by western blotting using a panel of immune mouse sera. Dominant antigens of approximate MR 30-33, 21 and 25 x 10(3) were common to tachyzoites of all strains, however, there were significant quantitative and qualitative differences in the antigen profiles, indicating a moderate degree of strain specific polymorphism in tachyzoite antigens. We found no specific association between antigenic variation and strain virulence. Comparison of tachyzoite and bradyzoite antigens from homologous strains (RRA, DEG, ME49) confirmed the existence of stage specific antigens and demonstrated a conserved antigen profile among bradyzoites.     

Redescription of Hammondia hammondi and its differentiation from Toxoplasma gondii

Hammondia hammondi is a protozoan parasite that, until 1975, was misidentified as Toxoplasma gondii. Recently, the validity of H. hammondi has been questioned. In this article, the authors redescribe the parasite and its life cycle, provide accession numbers to its specimens deposited in a museum, and distinguish it structurally and biologically from T. gondii. Hammondia hammondi was found to be structurally, biologically, and molecularly different from T. gondii.     

Whole genome profiling of spontaneous and chemically induced mutations in Toxoplasma gondii

Background

Next generation sequencing is helping to overcome limitations in organisms less accessible to classical or reverse genetic methods by facilitating whole genome mutational analysis studies. One traditionally intractable group, the Apicomplexa, contains several important pathogenic protozoan parasites, including the Plasmodium species that cause malaria.Here we apply whole genome analysis methods to the relatively accessible model apicomplexan, Toxoplasma gondii, to optimize forward genetic methods for chemical mutagenesis using N-ethyl-N-nitrosourea (ENU) and ethylmethane sulfonate (EMS) at varying dosages.

Results

By comparing three different lab-strains we show that spontaneously generated mutations reflect genome composition, without nucleotide bias. However, the single nucleotide variations (SNVs) are not distributed randomly over the genome; most of these mutations reside either in non-coding sequence or are silent with respect to protein coding. This is in contrast to the random genomic distribution of mutations induced by chemical mutagenesis. Additionally, we report a genome wide transition vs transversion ratio (ti/tv) of 0.91 for spontaneous mutations in Toxoplasma, with a slightly higher rate of 1.20 and 1.06 for variants induced by ENU and EMS respectively. We also show that in the Toxoplasma system, surprisingly, both ENU and EMS have a proclivity for inducing mutations at A/T base pairs (78.6% and 69.6%, respectively).

Conclusions

The number of SNVs between related laboratory strains is relatively low and managed by purifying selection away from changes to amino acid sequence. From an experimental mutagenesis point of view, both ENU (24.7%) and EMS (29.1%) are more likely to generate variation within exons than would naturally accumulate over time in culture (19.1%), demonstrating the utility of these approaches for yielding proportionally greater changes to the amino acid sequence. These results will not only direct the methods of future chemical mutagenesis in Toxoplasma, but also aid in designing forward genetic approaches in less accessible pathogenic protozoa as well.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-354) contains supplementary material, which is available to authorized users.     

Withdrawal of skeletal muscle cells from cell cycle progression triggers differentiation of Toxoplasma gondii towards the bradyzoite stage

Toxoplasma gondii is a widespread intracellular parasite of mammals and birds and an important opportunistic pathogen of humans. Following primary infection, fast‐replicating tachyzoites disseminate within the host and either are subsequently eliminated by the immune system or transform to latent bradyzoites which preferentially persist in brain and muscle tissues. The factors which determine the parasites' tissue distribution during chronic toxoplasmosis are unknown. Here we show that mouse skeletal muscle cells (SkMCs) after differentiation to mature, myosin heavy chain‐positive, polynucleated myotubes, significantly restrict tachyzoite replication and facilitate expression of bradyzoite‐specific antigens and tissue cyst formation. In contrast, proliferating mononuclear myoblasts and control fibroblasts enable vigorous T. gondii replication but do not sustain bradyzoite or tissue cyst formation. Bradyzoite formation correlates with upregulation of testis‐specific Y‐encoded‐like protein‐2 gene expression (Tspyl2) and p21^Waf1/Cip1 as well as downregulation of cyclin B1 and absence of DNA synthesis, i.e. a cell cycle arrest of syncytial myotubes. Following infection with T. gondii, myotubes but not myoblasts or fibroblasts further upregulate the negative cell cycle regulator Tspyl2. Importantly, RNA interference‐mediated knock‐down of Tspyl2 abrogates differentiation of SkMCs to myotubes and enables T. gondii to replicate vigorously but abolishes bradyzoite‐specific gene expression and tissue cyst formation. Together, these data indicate that Tspyl2‐mediated host cell cycle withdrawal is a physiological trigger of Toxoplasma stage conversion in mature SkMCs. This finding might explain the preferred distribution of T. gondii tissue cysts in vivo.     

Identification and characterization of differentiation mutants in the protozoan parasite Toxoplasma gondii

Two forms of the protozoan parasite Toxoplasma gondii are associated with intermediate hosts such as humans: rapidly growing tachyzoites are responsible for acute illness, whereas slowly dividing encysted bradyzoites can remain latent within the tissues for the life of the host. In order to identify genetic factors associated with parasite differentiation, we have used a strong bradyzoite-specific promoter (identified by promoter trapping) to drive the expression of T. gondii hypoxanthine-xanthine-guanine phosphoribosyltransferase (HXGPRT) in stable transgenic parasites, providing a stage-specific positive/negative selectable marker. Insertional mutagenesis has been carried out on this parental line, followed by bradyzoite induction in vitro and selection in 6-thioxanthine to identify misregulation mutants. Two different mutants fail to induce the HXGPRT gene efficiently during bradyzoite differentiation. These mutants are also defective in other aspects of differentiation: they replicate well under bradyzoite growth conditions, lysing the host cell monolayer as effectively as tachyzoites. Expression of the major bradyzoite antigen BAG1 is reduced, and staining with Dolichos biflorus lectin shows reduced cyst wall formation. Microarray hybridizations show that these mutants behave more like tachyzoites at a global level, even under bradyzoite differentiation conditions.     

Immunomodulating effects of Toxoplasma gondii occur at an early stage of infection

Abstract An antibody to a 60-kDa protein associated with membrane-bound ribosomes (MBRP) in Staphylococcus aureus was shown to cross-react with a 64-kDa protein in Bacillus subtilis . Evidence is presented suggesting that this Bacillus protein is identical to a 64-kDa protein, possibly involved in protein secretion, described by Horiuchi et al. [Proc. Natl. Acad. Sci. USA 80 (1983) 3287–3291). Both the 60-kDa staphylococcal protein and the 64-kDa Bacillus protein were precipitated as a complex with three other proteins when immunoprecipitated with the staphylococcal MBRP antibody.     

Types of cells involved in antigen-stimulated and spontaneous rosette formation with Toxoplasma gondii.

Antigen-binding cells were identified by using rosette formation of Toxoplasma gondii and defined lymphoid populations under different experimental conditions. Treatment of immunized spleen cell suspensions with anti-Thy 1 serum plus complement inhibited 5 to 29% of the rosette-forming cells (RFC). Higher numbers of thymus-derived lymphocyte-RFC were obtained after incubation at 4 degrees C and by the centrifugation method than by simple incubation at 20 degrees C. RFC were also observed with thymocytes. Combined treatment with anti-Thy 1 serum plus complement and depletion of adherent cells indicated that the major proportion, 46 to 70%, of RFC were B cells. Spleenocytes of nu/nu mice formed similarly high numbers of rosettes. Spontaneous RFC were observed in nonimmunized mice with both spleen and thymus populations. Numbers of rosettes varied considerably depending on the method and the source of cell population used. Removal of adherent cells from spleen suspensions resulted in RFC reduction of 14 to 25% in immunized and 14 to 33% in nonimmunized animals. Pretreatment with anti-mouse immunoglobulin inhibited completely the spleen and spontaneous thymus RFC and partially the thymus RFC in immunized animals.     

Monoclonal antibodies to Hammondia hammondi allowing immunological differentiation from Toxoplasma gondii

Five murine monoclonal antibodies (MAbs) were developed against purified sporozoites of Hammondia hammondi. Despite a large antigenic similarity between the 2 closely related coccidia, H. hammondi and Toxoplasma gondii, these MAbs only reacted with H. hammondi. Three MAbs, ID3, 3F2, and 4C9-7, recognized antigens of 38 kDa localized in rhoptries (1D3), in rhoptries and in oocyst and cyst walls (3F2), and in rhoptries and the apical region (4C9-7). Another MAb, 4C9-10, reacted with a 27-kDa antigen in dense granules of sporozoites and tachyzoites, and MAB 11B3 labeled an antigen of >94 kDa located in the pellicular membrane of the 3 stages of the parasite. These MAbs could be used for a rapid discrimination of the 2 coccidia in epidemiological studies or for diagnostic purposes in tissues.     

Cytoskeleton of Toxoplasma gondii

The cytoskeleton of Toxoplasma gondii was studied by electron microscopy using whole mounts of detergent-extracted parasites and thin sections of routine preparations, tannic acid-stained organisms, and detergent-extracted parasites. In whole mounts, the spiral arrangement of the 22 pellicular microtubules closely corresponded to the pattern of surface ridges seen previously by scanning electron microscopy and reflected the torsion of the parasite body during locomotion. The microtubules had free posterior ends and were anchored anteriorly in the polar ring, presumed to be a microtubule organizing center (MTOC). The insertions of the microtubules were supported by blunt projections of the polar ring, forming a cogwheel pattern in transverse view. The internal microtubules had 13 protofilaments and were twice the length of the conoid. They extended through the conoid and ended at the anterior preconoidal ring, presumably a second MTOC. The subunits of the conoid were arranged in a counterclockwise spiral when traced from base to tip, as were the pellicular microtubules. We postulate that as the conoid moves, the polar ring complex moves along the spiral pathway of the conoid subunits. Retraction of the conoid would then rotate the polar ring, producing the torsion of the body we observed by SEM.     

Toxoplasma gondii and mucosal immunity

Toxoplasma gondii, an intracellular parasite infects the host through the oral route. Infection induces a cascade of immunological events that involve both the components of the innate and adaptative immune responses. Alteration of the homeostatic balance of infected intestine results in an acute inflammatory ileitis in certain strains of inbred mice. Both the infected enterocytes as well as the CD4 T cells from the lamina propria produce chemokines and cytokines that are necessary to clear the parasite whereas CD8 intraepithelial lymphocytes secrete transforming growth factor beta that reduces the inflammation. In this review, we describe the salient features of this complex network of interactions among the different components of the gut-associated lymphoid tissue cell population that are induced after oral infection with T. gondii.     

Toxoplasma gondii tachyzoite-bradyzoite interconversion

During infection in the intermediate host, Toxoplasma gondii undergoes stage conversion between the rapidly dividing tachyzoite that is responsible for acute toxoplasmosis and the slowly replicating, encysted bradyzoite stage. This process of tachyzoite-bradyzoite interconversion is central to the pathogenesis and longevity of infection. Recent research has identified several stage-specific genes and proteins. However, despite recent advances in the understanding of Toxoplasma cell biology, more research is necessary to elucidate the complex events occurring during tachyzoite-bradyzoite interconversion. Here, a brief summary of this process is provided and a new method to characterize gene expression during interconversion is introduced.     

Immunization against Toxoplasma gondii

The emergence of Toxoplasma gondii as a major opportunistic organism in immunocompromised individuals and the steady increase in economic losses due to animal toxoplasmosis have fuelled the interest in vaccine development. In this review, Fausto Araujo addresses aspects of vaccination against T. gondii with regard to the problem posed by this parasite to pregnant women and to severely immunocompromised individuals.